Hafiza Shukor
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Preferred name
Hafiza Shukor
Official Name
Hafiza, Shukor
Alternative Name
Hafiza, S.
Shukor, H.
Main Affiliation
Scopus Author ID
56248038900
Researcher ID
AAK-7519-2020

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  • Publication
    Inhibition Study on the Growth of Clostridium Saccharoperbutylacetonicum N1-4 (ATCC 13564) for the Production of Biobutanol in ABE Fermentation
    ( 2023-01-01)
    Amin M.A.
    ;
    Hafiza Shukor
    ;
    Shoparwe N.F.
    ;
    Makhtar M.M.Z.
    ;
    Abdeshahian P.
    ;
    Oladokun S.O.
    In this present study, the inhibition effect of different concentrations of sugar degradation products in upstream processing (Hydroxymethylfurfural (HMF) and Furfural) and butanol as product inhibition in downstream processing on the growth of Clostridium saccharoperbutylacetonicum N1-4 (ATCC 13564) for the production of biobutanol in ABE Fermentation has been investigated. It was found that the presence of HMF and Furfural is non-toxic to cell growth and biobutanol production at concentrations below 3 g/L in the fermentation medium. The specific growth rate for both HMF and furfural was 0.067 h−1 and 0.066 h−1 respectively which is very close to the control medium without any inhibitor addition (0.068 h−1). Surprisingly, the addition of 1 g/L HMF has improved the yield of biobutanol from 0.020 g/g (control) to 0.034 g/g and the addition of 1 g/L Furfural has improved the yield of biobutanol to 0.042 g/g. Butanol inhibition study on the growth of C. saccharoperbutylacetonicum N1-4 (ATCC 13564) shows the decrease of specific growth rate from 0.071 to 0.065 h−1 when 5 g/L butanol was added. 15 g/L of butanol addition has caused a significant drop in the specific growth rate to 0.011 h−1 with an inhibitory effect of 85.7%. This result reveals that sugar degradation product has an inhibitory effect on the growth of microorganisms and biobutanol production at a certain concentration, and this ABE fermentation suffers from product inhibition. Therefore, the development of a robust strain is necessary to make this biobutanol industrially competitive even in the presence of the inhibitory compound.
  • Publication
    Efficiency of Fabricated Adsorptive Polysulfone Mixed Matrix Membrane for Acetic Acid Separation
    ( 2023-06-01)
    Pusphanathan K.
    ;
    Hafiza Shukor
    ;
    Shoparwe N.F.
    ;
    Makhtar M.M.Z.
    ;
    Zainuddin N.I.
    ;
    Jullok N.
    ;
    Siddiqui M.R.
    ;
    Alam M.
    ;
    Rafatullah M.
    The ultrafiltration mixed matrix membrane (UF MMMs) process represents an applicable approach for the removal of diluted acetic acid at low concentrations, owing to the low pressures applied. The addition of efficient additives represents an approach to further improve membrane porosity and, subsequently, enhance acetic acid removal. This work demonstrates the incorporation of titanium dioxide (TiO2) and polyethylene glycol (PEG) as additives into polysulfone (PSf) polymer via the non-solvent-induced phase-inversion (NIPS) method to improve the performance of PSf MMMs performance. Eight PSf MMMs samples designated as M0 to M7, each with independent formulations, were prepared and investigated for their respective density, porosity, and degree of AA retention. Morphology analysis through scanning electron microscopy elucidated sample M7 (PSf/TiO2/PEG 6000) to have the highest density and porosity among all samples with concomitant highest AA retention at approximately 92.2%. The application of the concentration polarization method further supported this finding by the higher concentration of AA solute present on the surface of the membrane compared to that of AA feed for sample M7. Overall, this study successfully demonstrates the significance of TiO2 and PEG as high MW additives in improving PSf MMM performance.
  • Publication
    Cyclic voltammetry studies of bioanode microbial fuel fells from batch culture of Geobacter sulfurreducens
    ( 2021-05-24)
    Shoparwe N.F.
    ;
    Makhtar M.M.Z.
    ;
    Sata S.A.
    ;
    Kew W.S.
    ;
    Mohamad M.
    ;
    Hafiza Shukor
    The present study aims to investigate the performance of batch culture of Geobacter sulfurreducens (G. sulfurreducens) for electrical current generation via cyclic voltammetry (CV) method. The CV study was performed with an applied voltage in the range of -0.1 to 0.1 V against the standard calomel electrode (SCE) during the cell growth and attachment of G. sulfurreducens on graphite felt and initial acetate concentration of 20 mM. The kinetics of electrode reaction was investigated by conducting CV experiments at different scanning rates of 5, 10, 20, 50 and 100 mVs-1. The diffusion coefficients (D) and heterogeneous electron transfer rate constant (ko) of both anodic and cathodic process were 1.04 x10-5 cm2.s-1, 1.73x10-6 cm2.s-1, 0.0004 cm.s-1 and 0.0011 cm.s-1, respectively. The obtained results showed that the anode exhibits high bioeletrocatalytic activity due to the attachment of G. sulfurreducens on the anode surface.
  • Publication
    Bibliometric Analysis on Biobutanol Production Research Trends from 2010-2022 using Scopus Database
    ( 2024-03-01)
    Amin M.A.
    ;
    Hafiza Shukor
    ;
    Makhtar M.M.Z.
    ;
    Ismail M.I.
    ;
    Yaakop N.S.
    ;
    Shafiq M.D.
    ;
    Shoparwe N.F.
    The global demand for biofuels as an alternative energy source is on the rise due to the anticipated decline in fossil fuel (gasoline). Biobutanol, among various biofuels, has garnered significant attention for its advanced features and suitability as an alternative to fossil fuels. Recognizing the importance of understanding research issues and fostering collaborative networks, this bibliometric analysis focuses on synthesizing research trends in biobutanol production over the past 12 years. Examining 357 Scopus-indexed documents, the study shows that over 80% of relevant articles were published after 2010, indicating the recent emergence of literature in this field. Citation analysis identifies publishing trends dating back to 2010, highlighting leading scholars. In 2016, 47 publications in Chemical Engineering were attributed to the field, with Professor Sahaid authoring 12 publications, primarily affiliated with UKM. Chemical Engineering comprised the predominant subject area, with articles constituting 75.07% of total publications. Bioresource Technology was the primary source title, and the keyword Biobutanol was frequently associated with the research (92.16%). UKM led in institutional contributions with 12 publications, while India had the highest total publications at 17.65%, and Malaysia contributed 6.44%. The majority of publications (88.24%) originated from journal publications, and English was the predominant language, accounting for 96.64% of the publications. This paper underscores the recent surge in biobutanol research and the importance of collaborative efforts for further advancements.
  • Publication
    Microbial Fuel Cell Technology as Advanced Sewage Sludge Treatment
    ( 2023-01-01)
    Mohd Sabri M.N.I.
    ;
    Mohd Abdul Rasik N.A.
    ;
    Pusphanathan K.
    ;
    Mohd Zaini Makhtar M.
    ;
    Hafiza Shukor
    The microbial fuel cell (MFC) has emerged as an innovative and sustainable renewable energy technology, offering a potential alternative to address the global energy crisis. Operating through electrochemical processes, MFCs harness the power of electrogenic bacteria (EB) as biocatalysts to generate electricity. This chapter highlights the untapped potential of sewage sludge, derived from wastewater treatment, as a valuable fuel source within the MFC system. Extensive research has demonstrated the abundance of organic components present in sewage sludge, making it highly amenable to degradation through microbiological pathways within the MFC. Despite the lack of large-scale commercial utilization of MFC technology in wastewater treatment plants, the significant progress and promising findings indicate its effectiveness in addressing the challenges associated with sewage sludge management. The MFC system not only facilitates the simultaneous generation of energy but also contributes to bioremediation efforts. The redox potential inherent in MFCs enables this dual functionality, effectively integrating energy production with the treatment of sewage sludge. This chapter sheds light on the potential of MFC technology as an advanced approach for sewage sludge treatment. By harnessing the capabilities of electrogenic bacteria and capitalizing on the rich organic composition of sewage sludge, MFCs offer a sustainable solution that can simultaneously address energy needs and promote efficient waste management in wastewater treatment plants. The abundant and promising data accumulated thus far underscore the viability and potential of MFCs in mitigating the challenges associated with sewage sludge waste.
  • Publication
    Formulation of selective hydrophobic deep eutectic oil-in-water nanoemulsion as green fungicides for mitigating anthracnose fungus Colletotrichum gloeosporioides
    ( 2023-12-01)
    Gidado M.J.
    ;
    Ahmad Anas Nagoor Gunny
    ;
    Wongs-Aree C.
    ;
    Subash Chandra Bose Gopinath
    ;
    Makhtar M.M.Z.
    ;
    Hafiza Shukor
    Hydrophobic deep eutectic nanoemulsions derived from fatty acids and terpenes (referred to as HyDEN) were introduced as potential nano-coating to effectively combat anthracnose during the postharvest preservation of fruits. Anthracnose primarily caused by the Colletotrichum gloeosporioides species is known for causing substantial damage to fruits. Synthetic fungicides have proven to be effective but come with environmental, health, and safety concerns. In this study, hydrophobic deep eutectic solvents (HDESs) were evaluated for their physical properties to identify the most suitable HDES for the formulation of HyDEN. Menthol-Thymol (MT) at 1:1 and 2:1 ratio met the criteria and was chosen for the formulation of HyDEN. HyDEN (MT-N 1:1) displayed a higher zeta potential value and smaller mean droplet diameter and then tested for its antifungal properties against C. gloeosporioides compared with selected antifungal agents. HyDEN (MT-N 1:1) exhibited strong antifungal activity against C. gloeosporioides and was attributed to its potent mode of action, binding affinity, and rapid onset compared to HDES and fungicide (Globus 5.5). This study also investigated how HyDEN (MT-N 1:1) affects mycelial growth, cell membrane permeability, and cellular leakage of C. gloeosporioides, highlighting its superior disruption of cell membranes compared to HDES and Globus 5.5. This research presents an eco-friendly alternative to the use of toxic chemicals and showcases an innovative and sustainable approach to controlling anthracnose in postharvest fruit preservation.
  • Publication
    Green Renewable Energy: Microbial Fuel Cell Technology
    ( 2023-01-01)
    Tuesday M.
    ;
    Pusphanathan K.
    ;
    Sobri M.F.M.
    ;
    Makhtar M.M.Z.
    ;
    Shoparwe N.F.
    ;
    Hafiza Shukor
    Microbial fuel cells (MFCs) are a bio-electrochemical system designed to generate energy by using electrons obtained from biological processes catalyzed by microorganisms. In MFCs, electrons are transmitted from the anode compartment (the negative terminal) to the cathode compartment (the positive terminal) via a conductive substance. Electrons are mixed with oxygen at the cathode, while protons diffuse via a proton exchange membrane. MFCs need continuous electron release from the anode and electron consumption from the cathode. Using microorganisms for effective conversion, MFC technology promises to produce clean energy from waste products produced by civilization. This technology, in contrast to renewable energy sources, recycles trash and energy created by our civilization and returns them to us, therefore reducing the adverse side effects of environmental degradation. This article examines the historical pattern of energy usage in Malaysia. In conjunction with that, this paper will review the principles of MFCs. Several designs of microbial fuel cells are utilized in this study. There has been variation in power density outcomes. Single-chamber, double-chamber, tubular, and flat-plate MFCs are examples of MFCs. Nonetheless, double-chamber and single-chamber MFCs are the focus of this paper. The substrate utilized affects the performance of MFCs; thus, several widely used substrates are also examined.
  • Publication
    Biomass to biobutanol: Current trends and challenges
    ( 2024-08-23)
    Amin M.A.
    ;
    Hafiza Shukor
    ;
    Shoparwe N.F.
    ;
    Makhtar M.M.Z.
    ;
    Jalil R.
    The term "biofuel" refers to a liquid or gas fuel obtained mostly from biomass for use in transportation. Biobutanol is a potential replacement biofuel for fossil-based liquid fuels as they become depleted. Biobutanol is a transportation fuel that may be simply combined with either gas or petrol at any ratio. Clostridia are the most prevalent fermentative organisms used in biobutanol production. It might well be recognized for its ability to use the acetone-butanol-ethanol (ABE) fermentation route to convert various types of renewable biomass to biobutanol. Various aspects of biobutanol fermentation, including butanol toxicity and product titer, have also been addressed. The recent advancement in lignocellulosic biomass treatment technology, which is significantly greener and safer for the environment, has been clearly articulated. This chapter also covers several metabolic engineering and simple engineering laboratory approaches such as Adaptive Laboratory Evolution (ALE) for strain improvement to overcome butanol toxicity. These biobutanol difficulties could be solved to improve microorganism resistance to high solvent concentrations and hence increase biobutanol output. The final section of this chapter will discuss the future of biobutanol production as a new sustainable and renewable future transportation fuel. Overall, this chapter will provide a better grasp of current trends and issues in biomass-based biobutanol production.
  • Publication
    Arthropods-mediated green synthesis of Zinc oxide nanoparticles using cellar spider extract a biocompatible remediation for environmental approach
    ( 2024-06)
    Muzamir Isa
    ;
    Muhammad Nur Aiman Uda
    ;
    M. A. R. Irfan
    ;
    Uda Hashim
    ;
    Subash Chandra Bose Gopinath
    ;
    Hafiza Shukor
    ;
    MRM Huzaifah
    ;
    Maimunah Mohd Ali
    ;
    Nur Hulwani Ibrahim
    ;
    Muaz Mohd Zaini Makhtar
    ;
    Ng Qi Hwa
    ;
    Mohd Khairul Rabani Hashim
    ;
    Zainal Abidin Arsat
    ;
    Nor Azizah Parmin
    ;
    Liyana Ahmad Sofri
    ;
    Mahfuz Affif Mohd Ruslan
    ;
    Tijjani Adam
    This study presents an eco-friendly approach to synthesizing zinc oxide nanoparticles (ZnO NPs) using extracts from cellar spiders, addressing environmental and health concerns associated with conventional methods. The spider extract efficiently reduced zinc acetate dihydrate, and the synthesized ZnO NPs underwent comprehensive quantitative characterization, including size, shape, morphology, surface chemistry, thermal stability, and optical properties using Fourier-transform infrared spectroscopy (FTIR), X-ray diffraction (XRD), zeta potential measurements, thermogravimetric analysis (TGA), and UV-vis spectroscopy. The nanoparticles exhibited intended characteristics, and their adsorption capability for methylene blue (MB) was quantitatively assessed using the Freundlich isotherm model and pseudo-second-order kinetic model, providing numerical insights into MB removal efficiency. The study demonstrates the potential of these green-synthesized ZnO NPs for applications in environmental remediation, wastewater treatment, and antibacterial therapies, contributing to both sustainable nanomaterial development and quantitative understanding of their functional properties.
  • Publication
    Overview of Sludge in Waste Treatment Plant
    ( 2023-01-01)
    Kobe J.
    ;
    Shafiq M.D.
    ;
    Alkarimiah R.
    ;
    Yaser A.Z.
    ;
    Hafiza Shukor
    ;
    Mohd Zaini Makhtar M.
    The treatment of wastewater in sewage treatment plants results in the generation of sewage sludge, which is a muddy residue that can exist in solid, semi-solid, or liquid form. Sewage sludge comprises a complex mixture of proteins, carbohydrates, detergents, phenols, and lipids, as well as harmful and dangerous organic and inorganic contaminants. The production of sewage is a result of the combination of domestic and industrial wastes, which typically contains over 99% water. The production of sewage is a result of contributions from various sources, including residential, institutional, commercial, and industrial facilities. This book chapter provides an overview of sludge in waste treatment plants, focusing on the terminology of wastewater treatment plants (WWTPs), the typical processes used in wastewater treatment, the constituents of sludge, rules and regulations governing WWTPs, and current methodologies employed for handling sewage sludge. The chapter provides insight into the complexities of managing sewage sludge, which is a crucial aspect of wastewater treatment, as it poses environmental and health hazards. The chapter highlights the importance of effective management of sewage sludge, emphasizing the need for sustainable approaches that ensure safe disposal and minimize environmental impact.